Title :
Dual process dielectric formation for decoupling capacitors on flexible substrates
Author :
Raghuveer, Rohit ; Burkett, Susan L. ; Schaper, Leonard W. ; Ulrich, Richard K. ; Geil, Robert ; Rogers, Bridget
Author_Institution :
HiDEC, Arkansas Univ., Fayetteville, AR, USA
fDate :
31 May-3 June 2005
Abstract :
Large area, high density integrated capacitors within printed wiring boards can provide a substantial decoupling capacitance with very low parasitic inductance. Tantalum pentoxide (Ta2O5) is an excellent dielectric for this application due to the relatively high dielectric constant (∼22-24), however the difficulty of fabricating large, defect-free capacitors has thus far prevented the realization of practical applications. High performance capacitors with Ta2O5 dielectric have been developed with a two step oxidation scheme at the High Density Electronics Center (HiDEC) at the University of Arkansas. The two step oxidation scheme consists of reactive sputtering followed by anodization. Thin films of Ta2O5 were deposited by reactive sputtering on silicon and also on Upilex® covered glass wafers using DC magnetron sputtering with a gas flow ratio of 10/90 O2/Ar. In the two-step oxidation scheme, anodization is performed after reactively sputtering tantalum oxide films to obtain a densified oxide structure. The electrical and physical properties of these two step oxidized sputtered/anodized tantalum oxide films are shown to be superior to those of tantalum oxide films prepared by either anodization or sputtering alone. This work has shown that Ta2O5 dielectric material is a potential dielectric for integrated capacitors in advanced packaging applications.
Keywords :
anodisation; capacitors; dielectric materials; oxidation; permittivity; silicon; sputter deposition; substrates; tantalum compounds; thin films; DC magnetron sputtering; Si; Ta2O5; anodization; decoupling capacitance; decoupling capacitors; dielectric constant; dielectric formation; dielectric material; electrical property; flexible substrates; glass wafers; high density integrated capacitors; parasitic inductance; physical property; printed wiring boards; reactive sputtering; tantalum oxide film; thin films; two-step oxidation scheme; Capacitors; Dielectric substrates; Dielectric thin films; High-K gate dielectrics; Inductance; Oxidation; Parasitic capacitance; Semiconductor thin films; Sputtering; Wiring;
Conference_Titel :
Electronic Components and Technology Conference, 2005. Proceedings. 55th
Print_ISBN :
0-7803-8907-7
DOI :
10.1109/ECTC.2005.1441998